US2687783A - Separation of gases and vapors in a fluidized adsorption process - Google Patents

Description

Aug. 31, 1954 c. H. WATKINS 2,687,783

SEPARATION OF GASES AND VAPORS IN A FLUIDIZED ADSORPTION PROCESS Filed Jan. 27, 1950 Patented Aug. 31, 1954 SEPARATION OF GASES AND VAPORS IN A FLUIDIZED ABSORPTION PROCESS Charles H.Watkins, Western Springs, 111., as-

signor to Universal Oil Products Company, Chicago, 111., a corporation of Delaware Application January '27, 1950, Serial No. 140,920

4 Claims. 1 This invention relates to an improved method for effecting the separation of fractionation of a mixed stream of gases and/or vapors in a fluidized adsorption processing operation. More particularly, the present improvement provides means for carrying out the fractionation or separation of desired components of a mixed stream by effecting the fluidized contactin of a subdivided solid adsorptive material and subsequently recovering desired fractions or gaseous com onents from separately withdrawn streams of the solid material, with each withdrawn stream being stripped in a fluidized manner within separate stripping zones.

Granular and finely divided adsorptive materials, such as chanlclays, gels, activated carbons etc, have been used commercially in various ways to effect the recovery of desired solvents, gases or vapors, as well as in the fractionation of a mixed Vaporousstream as encountereddn petroleum refining operations. The contacting of the adsorptive material has been carriedout in various ways, such as by the use of fixed beds of material, wherein the fluid material to be treated is caused to flow over or through the fixed bed, or alternatively, in a contacting method having the adsorbent material mixed with the liquid or solution to be treated, and subsequently settled or filtered out of the liquid stream after the contactin operation. More recently, the contacting of adsorptive material has been effected in a moving bed method, With the separation or fractionation operation being carried out in an elongated vertically disposed column. However, the moving bed methods have in general utilized rather elaborate mechanical or lifting means for maintaining the continuous circulation of the solid material through the vertical column and its various contacting zones. In addition, special flow distributing and disengaging decks have been required to control and regulate the flow of the descending bed of particles, and to effect the release of the desired gaseousfractions.

It is a principal object of the present inventic-n to provide a continuous fluidized operation which will elieot the separation or fractionation of a mixed gaseous and/or vaporous stream effecting the recovery of substantially pure desired fractions, with the fluidized operation providing the benefits of efiicientuniform and thorough contacting.

It is another object of the present invention to provide an improved fluidized contacting operation for the separation and/0r fractionation of desired components from a mixed stream, by

effecting both fluidized adsorptive contactin and subsequent fluidized stripping of separately withdrawn streams of adsorptive particles and fractions, which are separately withdrawn from vertically spaced portions of the fluidized contacting bed.

A further object of the invention is to provide fluidized contacting in an adsorption operation, wherein the fluidized countercurrent contacting of the adsorptive material and charge stream is carried out in a regulated controlled manner through the use of a packing material placed in the fluidized contactin zone.

It is a still further object of the invention to provide for improved fluidized stripping within separate confined stripping zones, whereby to recover relatively pure desired fractions or gas streams, and in turn provide for the regulated return of the stripped adsorptive material to selected portions of the contacting zones.

a fluidized bed of particles of the adsorptive material in a vertically disposed contacting and adsorption column, passing the mixed stream upwardly through the particle bed and effecting the fluidized contacting of the particles therein, continuously withdrawing desired side out streams of particles from vertically spaced portions of the contacting zone with desired fractions thereon, separately stripping side out streams of particles within separate confined stripping zones with a gaseous stripping medium, separately withdrawing the desired side out fractions from each of the separate stripping zones, discharging the resulting stripped particles from each stripping zone, and returning them to the contacting and adsorption zone for reuse therein.

The stripping medium may be high temperature steam, or other suitable inert gaseous meeffected externally of the adsorption zone, as they are recycled thereto, or alternatively cooling may be effected within the upper portion of the adsorptive column by indirect heat exchange with a suitable cooling medium being circulated through suitable heat exchange means.

In accordance with.the present .invention, .a single elongatedfluidized bed of particles is'maintained in the contacting and adsorption zone and the fluidization maintained by the countercurrent upward passage of the charge stream, the latter being introduced at the lowertendi dithe-cohtacting column. The heavier component of-the' mixed charge stream is adsorbed by the,par.ticles-.witl'1in the lower portion of the .fluidized bed, ithus a stream of particles being withdrawn from ,this lower portion thereof will contain primarily only the heavier gaseous or vaporous componentof the charge stream. The remaining components pass upwardly through the adsorption zone, and in the .next higherportion of thefluidized bed a next heavier component is adsorbedby-theparticlesftherein, and is primarily withdrawn with a side stream ofparticles continuously withdrawn from'ithe fluidizedi'bed. Likewise, the various desired fractions or gaseous components of the mixed charge stream may be withdrawn from the'upper vertically spaced portions of theifluid- 'ized bed inthe'contacting column. Ineach case,

the separatelywithdrawn side out streams of particles, with.desire'd .adsorbed fractions, aresepa- .rately stripped in.the confined stripping zones with steam or other gaseous stripping .medium,

as hereinbefore noted.

.While a plurality of. fractions may be fractionated or separated in accordance with themesent operation, preferably the adsorption of only .aifew desired fractions should be carried outin 'a single "contacting column, .with .the various heights of portions of the fluidized bed being varied in accordance with .the quantities of .material and contacting time needed to effect the .sub-

. stantially complete adsorption of the desired fractions which are to be withdrawn with the side material. Inotherwordsgthe packing material isprovidedinrelativelylarge size pieces which "will remain relatively static during the fluidized 'operationso'asto restrict the upward movement 'oithe .particles' from one. portion. of the contact- .ing column' to another, but will enhance the. over- "all' fluidizationproperties of the particles throughout the fluidized bed. This feature isa particullar advantage in a separation or fractionation "process; for the'selective adsorption of the desired fractions or.components ismade within the verticallyspaced portions of the fluidized bedof parti'cles and the restriction of repeated up and down movement ofparticles tends to prevent the contamination of fractions within portions of "the'continuous"fluidizedbed. On the other hand,

the'use of a packing material permits the'fluidization of particles larger than those which might normallygbe fluidized.

The operation Ofthepresent fluidized adsorptivesystem and additional advantagous features thereof will be more-.aparent.uponreference to the accompanying drawing and the following description thereof.

Referring .now to .the drawing, a. mixed .feed

etc. divided charwhich is effective in the separation .assumed that the feed stream .is ,-a-mixture of hydrocarbon vapors, including zethane,propane, and butane and heavier fractions as desired streams, as Well as undesired fractions or components including methane, hydrogen, C02, The :adsorptive material may be a finely ofthe lower boiling;petroleum fractions, however,

-as,hereinbefore noted, various adsorptive mate- ;rials have :been .used effectively in the industry for various separations, and a suitable adsorptive material should be utilized in all cases to-effectzthe desired separation. The char is utilized in a subdivided state, or small beads or spheres, which willbe readily fluidized ,bythe vaporous charge stream being introduced into the column, although in accordance with the preferred operation, packing material, such as Raschig rings or Berl saddles, are maintained in the interior of column3 and are supported by suitable perforated plates or grids ,5 at vertically spaced intervals, such that the fluidization of largerparticles will be enhanced and such that the up and down travel of the char particles may be controlled and regulated. A countercurrent fluidized operation is carried out in-the column. with thechar descending from the upper portion of the column to the lower end thereof against an upwardly rising feed stream. The packing material .does not prevent the gradual downward movement of the char, but-does preclude excessive upward surging .of the material within the contacting chamber, and also insures a uniform contacting of the bed of adsorptive material by the charge streamas it rises upwardly through the column.

In the lower portion of the fluidized bed, indicated as section 8, the butanes and heavier comto the stripping chamber 9. In the present embodiment, two additional streams of adsorptive material with desired adsorbed fractions are withdrawn from the column 3, the desired propane fraction being withdrawnfrom section II! of the fluidized bed, which is in turn above the lower section'fi at a pointwhich is substantially free of the butane and heavier fractions. The adsorptive .material with the desired propane fraction is withdrawn from .section Ill by way of conduit I! and control valve l2, with the stream bein introduced into a separate confined stripping chamber i3. Similarly, a desired ethane fraction is withdrawn from a still higher portionof the fluidized bed in the chamber 3. Section l4 thereof providing an intermediate zone which is substantially free of propane and heavier fractions permitting the continuous withdrawal of a side out stream of adsorptive material, and the desired ethane fraction, by Way of line I5 and control valve it which in turn connects with and supplies a confined stripping chamber IT.

The lighter fractionsandgases, together with a suitable purge stream, are passed from the upper adsorptive section 54 through a suitable cooling section It, and subsequently discharged alternatively, a suitable purge stream may be introduced into the upper cooling and purging section l8, in order to supply substantially clean adsorptive material to the lower portions of the fluidized bed for contacting the feed stream and for effecting the desired separation to selectively recover the desired fractions of the charge stream. The particle separator l9 permits the gaseous stream to be discharged from the upper portion of the chamber 3 by way of conduit 20 and outlet valve 2 I, while the char is recovered and returned to the fluidized bed by way of dip leg 22.

Separate stripping of the withdrawn streams of adsorptive material is continuously effected within each of the separate stripping zones, in accordance with the present invention, with a suitable stripping medium such as steam being introduced to chamber 9 by way of line 23 and valve 24, in order to countercurrently contact the descending bed of adsorptive material within the chamber 9. The removed butane and heavier fractions together with strippin medium, are discharged from the upper portion of the stripping chamber 9 .by way of line 25 and control valve 26, while stripped char particles are continuously passed from the lower end of the chamber by way of the line Z'I and control valve 28 to a suitable transfer or r ser line 29 providing for the return of the adsorptive particles to the fluidized bed within the adsorptive zone of chamber 3.

Steam or other suitable inert purging gas, such as flue gas, nitrogen, or the like, may be charged to the inlet of transfer conduit 29, having flow control valve 30, and providing means, for effecting the fluidized transfer of the particles through the conduit 29 to the upper portionof the contact chamber 3and into the purging and cooling zone l8.

Steam provides a desirable stripping medium for the removal of hydrocarbon vapors, such as described in the present embodiment, however, it is not intended to limit the improved operation to the use of any one stripping medium, for obviously other heated gaseous mediums may be used. For example, a heated stream of the gas or vapors being'adsorbed from a particular zone may also be used advantageously as stripping medium, thus where butaneand heavier gases are adsorbed by the particles passing to the strip ping chamber 9, a heated butane stream may be charged by way of line 23 to the lower end of the stripping chamber 9 to effect the desired stripping therein.

It is also a feature of the present operation,

to provide means for returning at least a portion of the adsorptive particles directly to the zone or portion of the fluidized contacting bed from which the stream of adsorptive material is being withdrawn. Transfer conduti 3|, with control valve 32, provides means for passing a portion of the stripped particles from chamber 9 and transfer conduit 29 directly to zone 6, or lower portion of the fluidized bed maintained in the adsorption chamber 3. The regulation of valve 32, together withthe control valve 33 in line 29, provides means for effecting the return of all or a portion of the stripped particles directly to the 1 lower portion of the fluidized bed by way of conduit 3|.

The stream of adsorptive particles withdrawn from section in of the fluidized bed in chamber 3 and transferred to strippingchamber l3 are valve 50;

contacted therein in a manner similar to that of chamber 3; by introducing steam or other stripping medium by way of line 34 and control valve 35into the lower portion of the chamber l3 to effect the counter-current contacting and stripping in a fluidized manner, and the removal of the desired propane fraction adsorbed on the particles. The propane fraction together with the stripping medium is discharged from the upper portion of chamber l3 byway of line 36 and. valve 31, while stripped adsorptive particles are discharged from the lower end of the chamber by way of conduit 38 and valve 39 into a transfer line 40. A suitable transporting and fluidizing medium, which may be steam or other suitable stripping and purging medium, is introduced to the transfer conduit 40, with control of flow regulated by valve 4|, and effects the transfer of A chamber |3 directly to that portion of the fluidized bed in the adsorptive column from which the particles were withdrawn, by way of transfer line 42 and control valve 43. Regulation and control of the quantity of material being returned to the intermediate portion of the fluidized bed and the upper portion of the bed within purging and cooling zone I8, may be regulated by the valve 43 and line 42 and a suitable flow regulating valve 44 within line 4|]. l

As described in connection with stripping chambers 9 and I3, the stream of adsorptive particles passing to stripping chamber I! by way of conduit l5, are countercurrently contacted and stripped in the latter zone by means of a stripping medium passed to the lower portion thereof by way of line 45 and control valve 46. A desired light ethane fraction together with stripping medium is discharged from the upper portion of stripping chamber I! by way of line 41 and valve48, with the stripped particles being continuously discharged from the lower end of the chamber byway of line 49 and control The adsorptive particles may then be continuously returned to the adsorption chamber 3 byway of a transfer line 5|, having control valve 52, and transfer riser line 29, or alternative- 1y, all or a portion of the material may be transfered by way of conduit 53 and control valve 54 to the section or portion M of the fluidized bed i in chamber 3 from which the adsorbed fraction .into the conduit 5|, with flow being controlled by valve 55, to effect the desired fluidized transfer of the adsorptive material through either or both of the conduits29 and 53.

It should also be noted, that a strippingmedium other than steam may be introduced into each of the respective stripping chambers l3 and H, the stripping medium being a heated relatively inert gaseous medium, or alternatively, a heated gas or vaporous fraction corresponding to that which is being adsorbed from that particular portion of the fluidized bed of adsorptive material in chamber 3 and being passed to each of the independent stripping chambers. Thus, a heated propane fraction may be introduced by way of line 34 to stripping chamber I3 to effect the desired stripping therein and the resulting product stream is not contaminated by a diluent or stripping medium. Likewise, in accordance :c aeaavea 1:7 'iiwithithe" present illiistnativecexample of the: improved ,-'a'dso1:ptive :sseparation pr {fractionation ssystem, :a :heated ethane .cstreammay be introcducedrby way ofiline 45: to-stripping chamber I1 -toi-effect the zremoval 'of the desired adsorbed ffractions.

.EThe present. adsorption systemasjprovided by rthis invention, rprovidesifon-an eflicient separa- -tion of fractions and is particularly advantageous i because r'of the 1 flexibility-10f operation which is :readilyaobtaine'd. .In the usual moving bed adsorptive system, all of the-contacting and adsorp- '-tive:material; passes through the entire length of athe, adsorption-zone,while in thegpresent opera- =tion, sseparate streams of adsorptive material are (continuously withdrawn from upper-and-inter- -;mediate;portions of:the bed-within the adsorpi'tion'rchamber, sothatshorterpaths of travel for nthelgparticles-result. Further, smaller quantities :bed. iIn' other-words, much of-the latent heat" which isgivenup to theadso'rptive material, as

the gaseous or vaporous fractions are continuously adsorbed by the;.particles, is continuously with- I drawn with -,the I streams. In addition the :con-

,tinuous introductionof stripped and cooled pari'tiClGS' to intermediate points ;of the fluidized bed, aid in reducing the temperature gradient of the .column'andfin turn provide more efficient'separation, of the mixed charge 1 stream. Indirect .cooling means, =asindicated by coil 56, is provided inithe upperportion of the bed. A suitable fluid cooling medium "may i be circulated through the coilw5ii-toeffect thecooling of the :adsorptive ma- :terial prior to entering the lower-,adsorptive zones 'of'the fluidized bed. Although not indicated in the drawing, .cooling-means'may be provided for heat exchange with'theparticles being returned 'by wayof each of the independent return lines which carry particles from the independent stripping zones to the various vertical sections or portionsnof the adsorption bed within "chamber 3,-whereby 1 to insure the return of relatively cool stripped adsorptive material into-.the various portions of 'theabed.

Although not shown in the drawingsuitable i'screening means may be'provided at'each particle withdrawal line to prevent the passage of the packing material alongwith the adsorptive ma- .terial.

It may again be noted, that it is notintended ,to .limit -.the present improved adsorptive, separating or fractionating method to'any one separation process, for obviously in addition to the separation of petroleum fractions as hereinbefore described, it is particularly eifective with other gaseous and'vaporous separations. For example, the recovery OfCOz from flue gas, the separation of acetylene from other oxidation gases, or the recovery of a particular petroleum .fraction such as ethane, propane, or ethylene, from natural gas or waste refinery gases. The :recoveryof ethylene, which is useful as a starting material in many chemical or synthesis \zprocesses; is also effectively accomplished by the qaresent adsorptive system, where :the desired ethylene -,stream is (produced -:along with pther hydrocarbon fractions and :oxidation products from an autothermicyor oxidative crackingzprocess.

'Iuclaim as my invention:

1. Amethod for effecting the continuous separation CO'fza 1 charge stream of mixed gaseous rand/or vaporousifractions in the presence of sub- ;divided :adsorbent :solid particles, which com- :prises, maintaining atdescen'ding fluidized bed of sai'drparticles within an elongated vertically disposed contacting and adsorption. zone containing larger sized non-adsorptive packing material which remains relatively static during the" fluidization of said particles, continuously passing'said mixed charge streamtothe lower portion of said "zone and upwardly'countercurrently to said de- "scending fluidized bed of'particles andeifecting thereby the contacting and fluidizing thereof, continuously withdrawing side-cut streams from vertically spaced portions of said fluidized bed within said adsorption zone with desired adsorbed fractions on each of said side-cut streams, separately stripping each stream of particles within separate confined stripping zones with a gaseous stripping medium, separately withdrawing recovered side-cut fractions from each .of said stripping :zones, discharging resulting stripped particles from each of said stripping zones and returning said strippedparticles to said adsorp- .tion.zone with atleast a,portion thereof from leachindividual stripping zone being returned to that portion of said adsorption column from which the particular side stream was withdrawn,

with the remainingportions of said strippedparticles being returned to .the upper ,portion .of

said adsorption column.

at each of saidzones, with the heated gaseous fraction beingintroduced to each ofrsaid-stripvpingzones corresponding to the fraction being .adsorbed by said side-cut stream of particles recovered at each of said separate zones.

4. A method foreffecting the continuous separation of -a.-mixed charge stream of gaseous and/or 'vaporous fractions in thepresence of a subdivided adsorbent solid :material which comprises, maintaining a descending fluidized .bed of subdivided particles of said material in an elongated vertically. disposed contacting and adsorption zone, with larger sized non-adsorptive packing material maintained within said .fluid- .ized contacting and adsorption zonewhereby fluidization of said particles'isregulated Within said descending bed of particles, continuously introducing said mixedstream to the-lower por- "tion of said contacting zone and passing it upwardly through said fluidized bed of particles and effecting the contacting and fluidizing of the latter in a countercurrent flow, continuously withdrawing side-cut streams of particles with the desired adsorbed fractionsthereon from vertically spaced portions ofsaid elongated fluidized bed of particles, separately stripping each'withdrawn stream of particles in separate confined stripping zones with agaseous stripping medium which countercurrently contacts and fluidizes said Withdrawn'particles, separately recovering desired side-cut fractions from each of said References Cited in the file of this patent UNITED STATES PATENTS Name Date Harris Aug. 16, 1932 Number Number '10 Name Date Holloway Nov. 23, 1943 Kiesskalt July 25, 1944 Arnold et al July 19, 1949 Gilliland Jan. 31, 1950 Small Apr. 10, 19 1 Odell June 19, 1951 Matheson July 24, 1951

Claims (1)

1. A METHOD FOR EFFECTING THE CONTINUOUS SEPARATION OF A CHARGE STREAM OF MIXED GASEOUS AND/OR VAPOROUS FRACTIONS IN THE PRESENCE OF SUBDIVIDED ADSORBENT SOLID PARTICLES, WHICH COMPRISES, MAINTAINING A DESCENDING FLUIDIZED BED OF SAID PARTICLES WITHIN AN ELONGATED VERTICALLY DISPOSED CONTACTING AND ADSORPTION ZONE CONTAINING LARGER SIZED NON-ADSORPTIVE PACKING MATERIAL WHICH REMAINS RELATIVELY STATIC DURING THE FLUIDIZATION OF SAID PARTICLES, CONTINUOUSLY PASSING SAID MIXED CHARGE STREAM TO THE LOWER PORTION OF SAID ZONE AND UPWARDLY COUNTERCURRENTLY TO SAID DESCENDING FLUIDIZED BED OF PARTICLES AND EFFECTING THEREBY THE CONTACTING AND FLUIDIZING THEREOF, CONTINUOUSLY WITHDRAWING SIDE-CUT STREAMS FROM VERTICALLY SPACED PORTIONS OF SAID FLUIDIZED BED WITHIN SAID ADSORPTION ZONE WITH DESIRED ADSORBED FRACTIONS ON EACH OF SAID SIDE-CUT STREAMS, SEPARATELY STRIPPING EACH STREAM OF PARTICLES WITHIN SEPARATE CONFINED STRIPPING ZONES WITH A GASEOUS STRIPPING MEDIUM, SEPARATELY WITHDRAWING RECOVERED SIDE-CUT FRACTIONS FROM EACH OF SAID STRIPPING ZONES, DISCHARGING RESULTING STRIPPED PARTICLES FROM EACH OF SAID STRIPPING ZONES AND RETURNING SAID STRIPPED PARTICLES TO SAID ADSORPTION ZONE WITH AT LEAST A PORTION THEREOF FROM EACH INDIVIDUAL STRIPPING ZONE BEING RETURNED TO THAT PROTION OF SAID ADSORPTION COLUMN FROM WHICH THE PARTICULAR SIDE STREAM WAS WITHDRAWN, WITH THE REMAINING PORTIONS OF SAID STRIPPED PARTICLES BEING RETURNED TO THE UPPER PORTION OF SAID ADSORPTION COLUMN.

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